Laser Pulse Phenomena and Applications

LASER PULSE PHENOMENA AND APPLICATIONS Edited by Dr. F. J. Duarte Laser Pulse Phenomena and Applications Edited by Dr...

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LASER PULSE PHENOMENA AND APPLICATIONS Edited by Dr. F. J. Duarte

Laser Pulse Phenomena and Applications Edited by Dr. F. J. Duarte

Published by InTech Janeza Trdine 9, 51000 Rijeka, Croatia Copyright © 2010 InTech All chapters are Open Access articles distributed under the Creative Commons Non Commercial Share Alike Attribution 3.0 license, which permits to copy, distribute, transmit, and adapt the work in any medium, so long as the original work is properly cited. After this work has been published by InTech, authors have the right to republish it, in whole or part, in any publication of which they are the author, and to make other personal use of the work. Any republication, referencing or personal use of the work must explicitly identify the original source. Statements and opinions expressed in the chapters are these of the individual contributors and not necessarily those of the editors or publisher. No responsibility is accepted for the accuracy of information contained in the published articles. The publisher assumes no responsibility for any damage or injury to persons or property arising out of the use of any materials, instructions, methods or ideas contained in the book. Publishing Process Manager Jelena Marusic Technical Editor Teodora Smiljanic Cover Designer Martina Sirotic Image Copyright Sebastian Schierenberg, 2010. Used under license from Shutterstock.com First published December, 2010 Printed in India A free online edition of this book is available at www.intechopen.com Additional hard copies can be obtained from [email protected]

Laser Pulse Phenomena and Applications, Edited by Dr. F. J. Duarte p. cm. ISBN 978-953-307-405-4

free online editions of InTech Books and Journals can be found at www.intechopen.com

Contents Preface Part 1

IX

Laser Emission and Propulsion Phenomena 1

Chapter 1

Pulse-Laser Powered Orbital Launcher 3 Hiroshi Katsurayma, Kimiya Komurasaki and Yoshihiro Arakawa

Chapter 2

“Impulsar”: New Application for High Power High Repetition Rate Pulse-Periodic Lasers 19 V.V. Apollonov

Chapter 3

The Effect of the Time Structure of Laser Pulse on Temperature Distribution and Thermal Stresses in Homogeneous Body with Coating 35 Aleksander Yevtushenko and Malgorzata Rozniakowska-Klosinska

Chapter 4

High-order Harmonic Generation 61 Krzysztof Jakubczak

Chapter 5

Burst Mode Q:switched Laser Pulses for Plasma Excitation in LIBS Analysis 83 Luis Ponce, Lesther Moreira, Eduardo de Posada, Miguel Arronte, Teresa Flores and Eugenio Rodriguez

Chapter 6

Numerical Simulations of Temperature-dependence on Distributed Bragg Reflector (DBR) and Performance Analyses for Proton-Implant/Oxide Confined VCSEL: Comparison with Transmission Matrix, Matrix Calculating Methods and Macleod Model 97 Tzu-Chiang Chen

Part 2 Chapter 7

Laser Diagnostics

115

Various Ambiguities in Generating and Reconstructing Laser Pulse Parameters Chandrasekhar Roychoudhuri

117

VI

Contents

Chapter 8

Infrared Thermo-Electric Photodetectors 143 W. Vandermeiren, J. Stiens, G. Shkerdin, V. Kotov, C. De Tandt and R. Vounckx

Chapter 9

Laser Pulses Characterization with Pyroelectric Sensors 165 Lorenzo Capineri and Marina Mazzoni

Chapter 10

Time-gated Single Photon Counting Lock-in Detection at 1550 nm Wavelength 191 Liantuan Xiao, Xiaobo Wang, Guofeng Zhang and Suotang Jia

Chapter 11

Laser Beam Diagnostics in a Spatial Domain 207 Tae Moon Jeong and Jongmin Lee

Part 3

Laser-matter Interactions

241

Chapter 12

Intensity Effects and Absolute Phase Effects in Nonlinear Laser-Matter Interactions. 243 Sándor Varró

Chapter 13

Multiphoton Selective Excitation and Analytical Control of Small Molecules in Intense Laser Fields: an Algebraic Model 267 Yujun Zheng

Chapter 14

Laser Plasma Accelerators: Towards High Quality Electron Beam Victor Malka

289

Chapter 15

Mechanisms of Nanoparticle Formation by Laser Ablation 309 Tatiana Itina and Karine Gouriet

Chapter 16

Ablation of 2-6 Compounds with Low Power Pulses of YAG:Nd Laser 323 Maciej Oszwaldowski, Janusz Rzeszutek and Piotr Kuswik

Chapter 17

Photoinduced Structural Changes of Doped SiO2 Glasses using Ultraviolet Laser Pulses Hiroaki Nishiyama and Junji Nishii

Part 4 Chapter 18

Chemical and Biological Applications

369

Hot Chemistry with Cold Molecules 371 Tapas Goswami and Debabrata Goswami

353

Contents

Chapter 19

UV-Laser and LED Fluorescence Detection of Trace Organic Compounds in Drinking Water and Distilled Spirits 389 Anna V. Sharikova and Dennis K. Killinger

Chapter 20

Optical Coherence Tomography: Development and Applications 409 Anderson Zanardi de Freitas, Marcello Magri Amaral and Marcus Paulo Raele

Chapter 21

High Resolution Biological Visualization Techniques Pavlina Pike, Christian Parigger and Robert Splinter

Chapter 22

CO2 Laser Pulse-Evoked Nocifensive Behavior Mediated by C-Fibers 459 Bai-Chung Shyu

433

VII

Preface Pulsed lasers are available in the gas, liquid, and the solid state. These lasers are also enormously versatile in their output characteristics yielding emission from very large energy pulses to very high peak-power pulses. Pulsed lasers are equally versatile in their spectral characteristics. This volume includes an impressive array of current research on pulsed laser phenomena and applications. Laser Pulse Phenomena and Applications covers a wide range of topics from laser powered orbital launchers, and laser rocket engines, to laser-matter interactions, detector and sensor laser technology, laser ablation, and biological applications.

F. J. Duarte Rochester New York, USA

Part 1 Laser Emission and Propulsion Phenomena

0 1 Pulse-Laser Powered Orbital Launcher Hiroshi Katsurayma1 , Kimiya Komurasaki2 and Yoshihiro Arakawa2 1 Yamaguchi

2 The

University University of Tokyo Japan

1. Introduction Some innovative plans in space development have been suspended because of high transportation costs of conventional launching systems. For example, the Japanese H2A rocket will cost $400 billion to launch a 1 GW output Solar Power Satellite (SPS) whose weight is 104 ton (Collins, 1993). A pulse-laser powered orbital launcher is a potential alternative to reduce those costs: a large payload ratio can be achieved because energy is provided from a ground-based laser and atmospheric air is used as a propellant. Figure 1 shows an air-breathing pulse-laser powered vehicle (“Lightcraft”) (Myrabo, 2001) with representative scales for 100 MW-class laser input. The vehicle forms plasma by focusing transmitted laser beams using a parabolic spike nozzle. The plasma absorbs the following part of the laser pulse while expanding outward. The resulting blast wave reflects on the nozzle surface and generates impulsive thrust. Figure 2 shows a schematic view of a pulse-laser powered launching system from the ground to a Geosynchronous Earth Orbit (GEO). In the initial stage of the launch, the vehicle closes its inlet and takes air from its rear area. This flight mode is called “pulsejet mode”. The inlet is opened and air is taken from the front end of the vehicle when the vehicle is accelerated sufficiently to be able to use ram-compression. This flight mode is called ”ramjet mode”. The inlet is again closed and on-board hydrogen is used as a propellant when the vehicle cannot obtain sufficient air at high altitudes. This flight mode is called “rocket mode.” Through these three modes, the vehicle is accelerated to reach orbital velocity. Several researchers have studied the feasibility for orbital launch using several laser propulsion systems (Toki, 1991; Kare, 1986; Humble et al., 1995; Phipps et al., 2000) , but most of them calculate flight trajectories using the thrust modeled with a fixed energy conversion efficiency. However, in an air-breathing propulsion system, the energy conversion efficiency evidently depends on its flight trajectory. The present article introduces our realistic performance modeling in three flight modes: the performance in the pulsejet mode is modeled using measured energy conversion efficiency (Mori et al., 2004, a) and Computational Fluid Dynamics (CFD) analysis (Katsurayama et al., 2008); the performance during the ramjet mode is computed using CFD analysis (Katsurayama et al., 2003); and the performance in the rocket mode is obtained analytically with the energy conversion efficiency computed using a thermochemical equilibrium calculation (Katsurayama et al., 2003). In addition, a transfer trajectory to the GEO is proposed. The launch trajectory to its geosynchronous transfer orbit (GTO) is computed using these realistic thrust models. Finally, the feasibility of the pulse-laser

2 4

Laser Pulses Laser Pulse Phenomena and Applications Bow Sho ck 1.5 m

100 kg, 1.5 m

3

0.60m, S~1 m2

Inflow

Liquid Hydrogen Tank

Payload

100 MW class Laser Beam

Thrust

Axis of Symmetry Sp Fo ike N cu sin ozz g M le irro r

40 kg, 0.7 m

3

Blast Wave Plasma

Fig. 1. Air-breathing pulse-laser powered vehicle(Myrabo, 2001). Ram-Compression

Blast

Inf low

Laser Plasma Wave

H

Mountain

Fine Weather

Ro ck et

Ra mj et

La Be ser am

Ex ha us t La Be ser am

Earth

Pu lse jet

Ex ha us t

La Be ser am

Ex ha su t

Re fill

2

Laser Beam (Light Highway) To Space

Fig. 2. A pulse-laser powered orbital launching system. powered orbital launcher is discussed through estimation of its achievable payload mass per unit beam power and costs (Katsurayama et al., 2009).

2. Performance modeling of pulse-laser powered vehicle 2.1 Momentum coupling coefficient and blast wave energy conversion efficiency

A momentum coupling coefficient Cm , which is the ratio of cumulative impulse to laser energy per pulse EL , is used as a performance indicator for laser propulsion. It is defined as Fdt EL , (1) Cm = I pulse

where F denotes thrust. The laser energy absorbed in a gas is converted to the blast wave energy Ebw , which is the source energy necessary to drive an equivalent blast wave in a calorically perfect gas Ushio et al. (2008): ρ et+r + 1/2u2 − ρ0 et+r + 1/2u2 dV, (2) Ebw = Vbw

0

35

Pulse-Laser PoweredOrbital OrbitalLauncher Launcher Pulse-Laser Powered

where Vbw is the volume surrounded by the blast wave, and ρ and 1/2u2 are the density and kinetic energy. Subscript 0 indicates the properties before laser incidence. Here, et+r is the sum of internal translational and rotational energy. On the other hand, the vibrational and electric excitation energy that are excited because of laser absorption are excluded from Ebw because they are newly stored in molecules and can not achieve pressure work as well as chemical potential energy. Because only Ebw contributes to F, Cm is proportional to the blast wave energy conversion efficiency ηbw ηbw = Ebw /EL .

(3)

Therefore, it is necessary to model the performance. 2.2 Explosion source model

According to our previous experiment (Mori et al., 2004, a;b; Mori et al., 2002) with a CO2 TEA laser, approximately 95 % of EL is absorbed in the form of the Laser Supported Detonation (LSD) wave (Raizer, 1977), and approximately its 45 % is converted to drive a blast wave. The remainder energy is confined in the form of chemical potential and electric excitation energy into rarefied plasma left near the focus: it is inconvertible to thrust, and is gradually lost in the form of radiation or dissipative heat flux to the surrounding. Therefore the remainder energy is excludable to reproduce this adiabatically expanding blast wave; the energy converted to the blast wave Ebw can be assumed to be equivalent to an instantaneous point explosion energy necessary to drive a blast wave with the same strength. Mori et al., 2004 (a) has investigated ηbw by comparing measured shock speed with that calculated using a similarity solution (Kompaneets, 1960) under the assumption of ideal air. The resulting ηbw in the standard atmosphere was 0.43±0.04, which was insensitive to EL within the tested range of 4.0–12.8 J (Mori et al., 2004, a). Although Wang et al. (2002) has computed the propagation of a LSD wave to investigate this energy conversion mechanism, such a computation is too expensive for our purpose to model ther thrust performance resulting from the adiabatic expansion of the blast wave whose time scale (the order of 100 μs) are much longer than that of energy absorption process (3.5 μs). In the performance modeling using our CFD analyses, the blast wave is driven by a pressurized explosion source with ηbw =0.43, whose radius is 1 mm and density is equal to that in the ambient atmosphere. Such an explosion source method (Steiner et al., 1998; Jiang et al., 1998; Liang et al., 2001; 2002) is familiar to simulate blast wave propagation whose time scale is much longer than that of energy input process. Measured (Mori et al., 2004, a) and computed (Katsurayama et al., 2008) propagation of a blast wave in free space are compared to validate the blast wave reproducibility of this explosion source. Figure 3 shows the histories of the shock front radius Rbw and Mach number Mbw of the blast wave in the case of EL =5.4 J. The CFD can reproduce the measured Rbw and Mbw after laser heating. Thereby the source model is used for computation to predict the thrust performance, and it was located at a laser focus. 2.3 Conical laser pulsejet

The thrust generation processes in a laser pulsejet with a conical nozzle were simulated to validate the performace modeling using our CFD analyses (Katsurayama et al., 2008). Figure 4 schematically shows sequential thrust generation processes in the laser pulsejet with a simple conical nozzle of its half apex angle α. In an energy absorption process (a), plasma is produced near the laser focus. The plasma absorbs laser energy in the form of a LSD wave. The large

4 6

Laser Pulses Laser Pulse Phenomena and Applications 0

14

Time t, μs (Experiment) 2 3 4 5 6

1

7

8

20

EL=5.4J

10

t) ) en FD im (C r e R bw xp (E w Rb M bw ( Ex pe rim en t) Laser heating

8 6 4 2 0

15

0

1

Shock front Mach number Mbw

Adiabatic expansion FD) M bw (C

Shock front radius Rbw, mm

12

2

10

5

3 4 5 6 Time t, μs (CFD)

7

8

9

0

Fig. 3. Comparison of the CFD and the experiment on Rbw and Mbw in the explosion in free space. (CFD: ηbw =0.43; Experiment (Mori et al., 2004, a) : ηbw =0.43±0.04) Axis of symmetry α

Laser Beam

Rn (a) Energy Absorption process

Blast wave

Plasma

(b) Blast wave expansion process Bl as tw a

ve

Air Air (d) Refill process

(c) Exhaust process

Fig. 4. Schematic of a laser pulsejet engine cycle. part of the absorbed energy is used to drive a high-pressure blast wave in the surrounding air. In a blast wave expansion process (b), the blast wave imparts an impulsive thrust directly to a nozzle wall; thereby, main thrust is produced. In exhaust (c) and refill (d) processes, the air in the nozzle is exhausted and fresh air is taken in. Additional thrust will be produced in these processes. Because the exhaust-refill prcoesses results from an adiabatically expanding blast wave after laser heating, an explosion source is used to drive the blast wave instead of solving a laser abosrption process. Figures 5 and 6 respectively show the thrust history and corresponding pressure contours of a conical laser pulsejet. Δp in the captions of pressure contours shows the interval of the contours. An explosion starts at t=0 (see Fig. 6(a)). A shock wave reaches the nozzle exit at t0 μs as shown in Fig. 6(b). F0 is the thrust at t= t0 . After t= t0 , the heated air starts to be exhausted and thrust decreases gradually. At t= t1 (see Fig. 6(c)), thrust becomes zero. Thrust becomes negative because of the rarefaction wave behind the shock wave and

57

Pulse-Laser PoweredOrbital OrbitalLauncher Launcher Pulse-Laser Powered 300

~ α=10 , r=0.4, EL=10J o

250

Thrust F, N

200 150 F0

100 50

t0 t1

t2

100

200

t3

t4

0 -50

0

300 400 Time t, μs

500

600

Fig. 5. Thrust history. (ηbw =0.43) thrust takes a minimum value at t= t2 . The gauge pressure becomes negative for the entire region inside of the nozzle, as seen in Fig. 6(d). At t= t3 (see Fig. 6(e)), thrust reverts to zero; subsequently, thrust has a second peak at t= t4 . After t= t4 , thrust oscillates and the oscillation attenuates gradually. Figure 7 shows measured (Mori et al., 2004, b) and computed relationships between Cm and α. The computation reproduces the Cm decreasing tendency. The processes until the shock front of a blast wave reaches the nozzle exit are similar regardless of the nozzle apex angle. However, after the blast wave leaves the nozzle edge, the behavior of the rarefaction wave induced behind the shock wave depends greatly on the nozzle apex angle. In the case of small apex angles, succsessive refilling mechanisms with vortices are activated by the prominently evolved rarefaction wave, in contrast, in the case of large apex angles, this mechanims do not appear due to the moderate evolution of the rarefaction wave. This difference was found to result in the decreasing tendency of the momentum coupling coefficient. More detailed descriptions of these phenomena is found in Katsurayama et al. (2008). Because the computed Cm is in good agreement with measured data in the cases of small α, our CFD analyses have the capability for predicting the thrust performace of a pulse-laser powerd launcher. Although the deviation from the measurement increases with increasing α, this unpredictability is insignificant because the cause is attributable to the not-optimized geomertical relation between the LSD propagation distance and nozzle length (Katsurayama et al., 2008). 2.4 Laser ramjet

Cm during the laser ramjet mode was computed in our previous CFD analyses (Katsurayama et al., 2003). A blast wave is again driven by an explosion source model with ηbw which depends on atmospheric pressure (Katsurayama et al., 2009). Figure 8 shows a part of computational results, and these results (Katsurayama et al., 2003) have showen that Cm in the ramjet mode is insensitive to laser energy EL and depends only on flight conditions. Therefore, the performance is obtained from the map of Cm , which is

6 8

Laser Pulses Laser Pulse Phenomena and Applications pmax

(a) t=0 μs (pmax =3.77×103 atm, pmin =1.00 atm, Δp=1.26×102 atm) pmax

(b) t=50 μs ∼ = t0 (pmax =3.99 atm, pmin =1.00 atm, Δp=9.98×10−2 atm) pmin pmax

(c) t=88 μs ∼ = t1 (pmax =2.27 atm, pmin =4.32×10−1 atm, Δp=6.14×10−2 atm)

pmin

pmax

(d) t=176 μs ∼ = t2 (pmax =1.18 atm, pmin =3.70×10−1 atm, Δp=2.70×10−2 atm)

pmin

pmax

(e) t=284 μs ∼ = t3 (pmax =1.18 atm, pmin =4.79×10−1 atm, Δp=2.34×10−2 atm) Fig. 6. Typical pressure contours of the conical laser pulsejet. constructed using CFD analyses under the conditions of 16 pairs of atmospheric density ρ∞ and flight Mach number M∞ . The map of Cm is shown in Fig. 9 with the fitting function of M∞ and ρ∞ Cm ( M∞ , ρ∞ ) = 0.04M2∞ − 1.81M∞ + 19.00 2 × 0.35 log10 ρ∞ + 5.01 log10 ρ∞ + 13.06 ,

(4)

which is used to calculate the flight trajectory. The value of Cm decreases with decreasing ρ∞ because of the decrease in a captured mass flow rate. It also decreases with increasing M∞ because the blast wave quickly leaves the nozzle because of the increase in the engine flow speed.

79


Momentum coupling coefficient Cm, mNs/J

0.45

~ r=0.4, EL=10J Experiment CFD

0.40 0.35 0.30 0.25 0.20 0.15 0.10 0.05 0

0

10 20 30 40 50 60 70 Half apex angle of a conical nozzle, deg.

80

Fig. 7. Relationship between Cm and α. (CFD: ηbw =0.43; Experiment: ηbw =0.43±0.04)

(a) At t=12 μs. (pmax =2.27 atm, pmin =2.1×10−2 atm, Δp=0.11 atm)

(b) At t = 20 μs. (pmax =4.63atm, pmin =2.1×10−2 atm, Δp=0.23 atm)

(c) At t = 38 μs. (pmax =4.27 atm, pmin =2.0×10−2 atm, Δp=0.21 atm) Fig. 8. Typical pressure contours of the laser ramjet: EL =400 J, H =20 km and M∞ =5.

8 10

Laser Pulses Laser Pulse Phenomena and Applications

Cm, N/MW

250 200 150 100 50 00

3

1 , kg/

m

yρ 10-1 nsit Flig 2 ht M 4 e d ach 6 ic -2 num 8 10 her ber p 10 s M mo At

Fig. 9. C m map of the laser ramjet. 2.5 Laser rocket

Because the vehicle flies in a near-vacuum environment in the rocket mode, its thrust depends only on the nozzle expansion ratio. The self-similar solution in a conical nozzle (Simons et al., 1977) is available to estimate Cm . Assume that the blast wave propagates in the hydrogen propellant expanding to a vacuum. In such a case, Cm is modeled as

Cm = 2m˙ p ηbw,rocket /PL sin2 α [2π (1 − cos α)] , (5) where m˙ p and PL respectively represent the mass flow rate of hydrogen propellant and time-averaged laser power. The apex angle of the nozzle cone α is set to 30°which is almost equivalent to the value of the Lightcraft used in the CFD analysis of the ramjet mode. The value of ηbw in the rocket mode is calculated analytically by solving the propagation of a LSD in hydrogen propellant using our previous numerical model (Katsurayama et al., 2003) obtained by combining a plain Chapman-Jouguet detonation relation and chemical equilibrium calculation, resulting in ηbw,rocket = 23.5%.

3. Feasibility of pulse-laser orbital launcher 3.1 Light highway

The pulse-laser powered orbital launcher requires a laser base with average output of 100 MW∼1 GW. For development of such a high-powered laser base, the cost of a laser transmitter is expected to predominate over the costs required for other systems such as cooling and power supply (Kare, 2004). Thereby, the cost-reduction of the laser transmitter is indispensable for the launching system. An optical phased array with diode lasers (Kare, 2004; Komurasaki et al., 2005) will reduce the cost because existing laser technology is applicable and mass-production effect is expectable. Moreover, launch using only a laser base is realistic. Furthermore, several obstacles on beam transmission should be assessed briefly to discuss the launching system feasibility. If the beam is a Gaussian beam whose respective aperture and wavelength are 1 m and 1 μm, the total spreading angle is 1.2×10−6 rad. The energy loss caused by beam diffraction is acceptable because the beam radius spreads to only 1.19 m at the


9 11

transmission distance of 500 km, which is the typical value required for the launching system. The beam spread, attenuation, and refraction caused by nonlinear effects of the atmosphere, such as the variation of atmospheric refraction index, thermal blooming, Rayleigh, Raman and Mie scattering, have been analyzed for the ORION project (Phipps et al., 1996; Cambell, 1996), which is intended to remove debris on orbits using a pulse laser. Nonlinear effects are inferred to be negligible for transmission with a beam power density under a threshold determined by a laser pulse width and wavelength. To avoid the whipping phenomenon of the beam center caused by atmospheric turbulence, the launch site should be built on the top of a mountain where the weather is expected to always be fine and for which scintillation caused by atmosphere is small. A location where an astronomical observatory has been built is suitable if a vehicle is launched at a time without clouds or turbulence. For example, Mauna Kea in Hawaii has no cloud cover for 90% of the days in a year. In addition, an ongoing study (Libeau et al., 2002) proposes a vehicle shape with which the vehicle can maintain its center axis parallel to the beam direction by generating thrust vector and torque automatically in the direction that allows it to retain aerodynamic stability. Both directions of the flight and beam can be maintained as vertical to the ground using this technology. Therefore, vehicle tracking and beam pointing are unnecessary for the launching system. The vehicle can be transferred to space along a “light highway” (Myrabo, 2001) constructed vertically from the ground, as shown in Fig. 2. 3.2 Proposed trajectory to GEO

Considering requirements for beam transmission, the vehicle is accelerated vertically in a short distance along the light highway. Figure 10 shows a trajectory to a GEO through the pulse-laser powered launcher and an upper-stage propulsion system for the Hohmann transfer. The vehicle is launched from the equator through the pulse-laser powered launcher; it is accelerated rapidly to ΔvL . The vehicle then reaches an apogee point beyond the GEO through inertial flight to use the ΔvL efficiently. The structure weight of laser propulsion is detached at the apogee point, and the upper-stage propulsion system is burned. The detached structure is attracted to the earth and it is incinerated during reentry into the atmosphere. Figure 11 shows the variation of ΔvL and the velocity increment ΔvH required for the Hohmann transfer with cut-off velocity vc , which is the flight velocity when laser propulsion is terminated. The required ΔvL and ΔvH are 18.85 and 1.84 km/s, respectively, if vc =10.6 km/s is chosen. Electric propulsion is available for the upper-stage propulsion system by virtue of an abundant electricity supply from the cells if solar cells are transferred to construct an SPS. Using the Hall thruster, whose specific impulse Isp,EP is 2000 s, the transfer to the GEO takes a spiral trajectory. As a result of calculating them by solving equations of motion (Spencer et al., 1995; Kluever et al., 1998) without trajectory optimization, the effective velocity increment Δvspiral (Spencer et al., 1995) through the upper-stage propulsion is estimated as 3.68 km/s. The resulting payload ratio λu of the upper stage is 2ηEP ( PEP /mu,0 ) λu = 1 − (6) 2 dt (1 − ε EP ) = 0.83. spiral gIsp,EP where the propulsion system efficiency ηEP and the structure weight coefficient ε EP are assumed respectively as 65% (Kluever et al., 1998) and 0.1. The ratio of power to the initial

10 12

Laser Pulses Laser Pulse Phenomena and Applications Acceleration kick

flight Inertial

apogee

GTO GEO ΔvL Earth

perigee Deceleration kick

Fig. 10. Proposed trajectory to GEO. 19.2

Δv

2.5

Δv

L

19.0

H

18.8 2.0

18.6 18.4

1.5 18.2 1.0 10.0

10.2

10.4 10.6 10.8 Cut-off velocity vc, km/s

Velocity increment through pulse laser launcher ΔvL, km/s

Velocity increment required for Hohmann transfer ΔvH, km/s

3.0

18.0 11.0

Fig. 11. Variation of the velocity increment through the pulse-laser powered launcher and the velocity increment required for the Hohmann transfer with cut-off velocity. upper-stage weight ( PEP /mu,0 ) is set to 100 W/kg in view of the ratio of power to weight of the 1 GW-output SPS. vc =10.6 km/s and λu =0.83 are used in the calculation of launch trajectories described in § 3.4. 3.3 Mode switching criteria

The pulsejet mode should be switched to the ramjet mode when the blast wave becomes free from propagation over the inlet because of the vehicle acceleration. However, numerous CFD analyses are necessary to model the timing correctly because it depends on E L and flight conditions. The present model therefore chooses the safest timing: the mode is switched when the flow in the vehicle is free from choking by laser heating. An engine cycle, as shown

11 13


Air

Inl et Sh oc kw av e

e zzl No

Isentropic expansion

External compression #0

#1

Isometric heating

#2 #3

Fig. 12. Engine cycle for assessing heat-choking. in Fig. 12, is analyzed to assess heat-choking. In this cycle, the air is taken in at location #0 through an effective inlet area (7) A0 = Sv × C.A.R., where Sv and C.A.R. are the maximum cross sections of the vehicle and the capture area ratio. The captured air is compressed externally from #0 to #1 as u 1 = ηd u 0

(8)

where u and ηd are the flow velocity of the air and diffuser efficiency. ηd and C.A.R. are obtained using CFD analysis on the Lightcraft. With increasing M∞ , ηd decreases from 0.72 to 0.62 and C.A.R increases from 0.31 to 0.71 (Katsurayama et al., 2004). The air is then expanded isentropically from #1 to #2 to delay heat-choking at #3. Finally, it is laser-heated isometrically from #2 to #3. The Mach number at #3 is calculated as

γRT3 = u2 γR T2 + ηbw ηtrans PL / Cp m˙ air M3 = u 3 Herein, T and m˙ air is temperature and the captured mass flow rate. Respectively, R, Cp and γ denote the gas constant, the constant pressure specific heat, and the specific heat ratio of ideal air. Furthermore, ηtrans is the transmission efficiency of the laser beam. The pulsejet mode is switched to the ramjet mode when (9) M3 = 1. In the ramjet mode, the mass flow rate taken from the inlet decreases with altitude because of the decrease in the atmospheric density. Finally, the acceleration of the vehicle becomes zero because of the balance between thrust and aerodynamic drag, at the time when the flight mode is switched to the rocket mode. 3.4 Computed launch trajectory and payload ratio

A launch trajectory to the GEO is calculated by solving the following equation of motion by the 4th order Runge-Kutta scheme. mv

dv 1 = F − ρ∞ v2 Sv Cd − mv g0 [ RE / ( RE + h)]2 dt 2

(10)

Therein, Sv , v and mv are the maximum cross sections of the vehicle, the flight velocity, and the vehicle weight. Also, g0 , RE and h respectively indicate the gravity acceleration on the ground, the radius of the earth and the flight altitude. An aerodynamic drag coefficient Cd is obtained using the CFD analysis on the Lightcraft; it varies from 0.15 to 0.64 depending

12 14

Laser Pulses Laser Pulse Phenomena and Applications 35 λ=0.48 λ=0.35 λ=0.10 g

.

Roc ket

L

P

/m

Pulsejet

1

P

L

0

0

/m

2

5 0

et mj Ra

4

P

10

6 M

et ck Ro

/m

8

15

v,0

=1 0.0

=1 0 v, /m L 10 P

=1 .47

0

v,

M

.0

/m PL

g

/k

W

47

=5

=1

0

v,

=5

W

M

v,0

P

20

/m L

.0

v,0

25

Ra m jet

Flight Mach number M

0 0.

g

/k

/k

W

M

L

vc=10.6 km/s 30

100 10 h, km (logscale)

50 100 150 200 250 300 350 400 450 Flight altitude h, km

Pulsejet

Fig. 13. Flight Mach number vs. flight altitude. on M∞ (Katsurayama et al., 2004). Flight conditions are determined by tracing the trajectory. Time-averaged thrust F in each mode is estimated using Cm modeled in § 2 as F = Cm ηtrans PL .

(11)

Herein, if the laser transmitter is the phased array with an effective broad aperture, the fraction of beamed energy contained in a main-lobe of beam is theoretically predictable. It is independent of the transmission distance; ηtrans is set to its predicted value of 72 % (Komurasaki et al., 2005) on the assumption that the nonlinear effects attributable to the atmosphere negligibly affect the beam transmission. As the result of the trajectory calculation, the payload ratio λ is estimated as (12) m˙ p dt [ mv,0 (1 − ε L )] λu , λ= 1− Rocket mode

where mv,0 is an initial vehicle mass and the upper stage payload ratio λu =0.83 is used (Katsurayama et al., 2009). The structure weight coefficient of the pulse-laser powered vehicle ε L is set to 0.1 in view of the simple structure of the vehicle. The vehicle is launched at h=4200 m equal to the altitude of Mauna Kea. The calculation is terminated when the vehicle is accelerated to the cut-off velocity (Katsurayama et al., 2009) vc =10.6 km/s. Figure 13 shows the trajectories and λ for several specific beam power PL /mv,0 . The ramjet period and λ decrease with decreasing PL /mv,0 . The ramjet mode becomes unavailable at PL /mv,0 1017 W/cm2) from plasma mirror oscillating at relativistic velocities on the surface of a solid state target (Quéré et al., 2006), or generation of HHG from interaction of IR femtosecond laser pulses with molecules (N2, H2+; Lorin et al., 2008).

2. Physical mechanisms of high-order harmonic generation If material is subjected to a strong electric field, nonlinear polarization of the material is induced. The magnitude of the arisen polarization strongly depends on the intensity of the incident radiation. At moderate and low intensity values the external electric field does not influence significantly the electronic structure of the irradiated atoms. The potential barriers can be just slightly modified and Stark effect can be observed. To great probability the atoms remain in their ground state and extension of their ground state wave function is of the order of Bohr radius ( 5.2917 ⋅ 10 -11 m ). All nonlinear phenomena taking place in this regime are well described by the perturbation theory. Thus it is referred as the perturbative regime of nonlinear optics. Comprehensive discussion on phenomena and related theory in the perturbative regime can be found e.g. in Boyd, 2003. Some of nonlinear optical phenomena in this regime are: • harmonic radiation generation (second, third, etc.), • optical parametric amplification, • optical rectification, • stimulated Raman scattering, • self-phase modulation, • self-focusing. However, when the electric field strength of the incident radiation is comparable to (or higher than) atomic electric field strength ( 5.142 ⋅ 1011 V/m ; Brabec & Krausz, 2000) then the potential barriers are strongly modified. With high probability the electrons from the most-outer atomic shells may be liberated either through the tunnel ionization or the abovebarrier ionization (depending on the external field strength; see Fig. 3 and Fig. 4). Subsequently, if the field is linearly polarized electron wave packets will start oscillatory motion. The amplitude of oscillations exceeds Bohr radius and cycle-averaged kinetic energy of electron wave packet surpasses binding energy (Brabec & Krausz, 2000). Range of intensities implying these phenomena defines the strong field nonlinear optics regime. In contrary to the perturbative regime, here, the nonlinear response of the polarization of the medium is affected by the ionization process. The nonlinear treatment can be only applied

64

Laser Pulse Phenomena and Applications

Fig. 3. Tunnel ionization. The atomic potential affected by the external electric field whose the field strength is comparable to the atomic fields. It is plausible that the electrons from the most-outer atomic will be unbound. This transition is often referred as optical field ionization (OFI).

Fig. 4. In this case, the applied electric field is higher than the atomic field strength. The atomic potential barrier is suppressed and electrons from most-outer shells are liberated through above barrier ionization. to an electron which is in very close vicinity of a parent ion. As soon as it is released by optical field its response is linear to the electric field and may be treated by classical laws of motion (Corkum, 1989; Corkum, 1993). Very interesting phenomena are present in the intermediate range of parameters, in the so called intermediate regime, i.e. between the perturbative and the strong field regimes. They include long-distance self-channeling when nonlinear Kerr effect causes beam focusing, on the one hand, and free electrons cause its defocusing, on the other. This interplay leads to the channeling of the propagating intense pulse (even at distances as long as a few meters). Another interesting phenomenon in this regime is multiphoton ionization, where the total amount of absorbed energy exceeds the ionization potential (Fig. 5). When electric field strengths are even higher, the nonlinearities become stronger. Electric field is able to optically liberate electrons from inner shells of the atom and the wiggling energy of an electron is comparable with its rest energy mc2. This is a launch of relativistic regime. Publications of crucial importance related to the intermediate to strong-field nonlinear optics regimes were made by Keldysh (Keldysh, 1965) and Ammonsov, Delone and Krainov (Ammosov et al., 1986). Keldysh defined a parameter, which was later named after him that allows determining whether tunneling or multiphoton process is dominant for particular experimental conditions. It reads:

65

High-order Harmonic Generation

Fig. 5. Multiphoton ionization process: n-photons are absorbed. The total energy of absorbed photons (n*hν; n - number of absorbed photons, h - Planck's constant, ν - light frequency) exceeds ionization potential.

γ=

Ip 2 ⋅Up

(1)

Where: Ip - is ionization potential of a nonlinear medium, Up - is ponderomotive potential, which is cycle-averaged quivering energy of an electron in the external laser field. It is defined as: Up =

e 2 ⋅ E0 2 4 me ⋅ ω 2

(2)

Where: e - stands for charge of electron, me - is mass of electron, E0 - external field amplitude oscillating at frequency ω. Substitution of constants leads to simplified relation: U p [ eV ] = 0.97 ⋅ 10 −13 I[ W / cm2 ]λ 2 [ μ m]

(3)

The laser field amplitude can be estimated from relation: E0 2 [V / cm] =

I[ W / cm2 ] 1 Z0 2

(4)

Where: I - is laser intensity [V/cm2], Z0 - is vacuum impedance. Z0 = μ0ε 0 = 377[V / A]

Where: µ0 - is vacuum permeability, µ0 =1.26 ⋅ 10 -6 [H/m] ,

(5)

66


ε0 - is vacuum permittivity, ε 0 =8.85 ⋅ 10 -12 [F/m] . If γ >> 1 multiphoton ionization dominates. However, if γ 1) iruv photoionization of atoms with higher harmonics, Phys. Rev. A, Vol. 54, No. 1, pp. 721-728 (1996).

5 Burst Mode Q:switched Laser Pulses for Plasma Excitation in LIBS Analysis Luis Ponce1, Lesther Moreira2, Eduardo de Posada1, Miguel Arronte1, Teresa Flores1 and Eugenio Rodriguez1 1CICATA-Altamira

km 14,5 Carretera Tampico Puerto industrial, Altamira 89600, Tamps, 2IMRE-Havana University, Vedado 10400, C. Habana, 1México 2Cuba

1. Introduction The Laser Induced Breakdown Spectroscopy (LIBS), is a technique that has been firmly established for the rapid determination of the elemental composition (Cremers, 2006). It relies on material ablation by using a short duration laser pulse with high density energy enough to produce plasma. By analyzing the light emitted by the plasma, it is possible to determine the elemental composition of practically any material. This technique has significant advantages over other conventional analytical techniques (Cremers, 2007; Rusak et al., 1998; Song et al., 1997). For example, requires no sample preparation, may be performed in solid, liquid or gas phase in samples with any shape or dimension. Moreover, it allows an in-depth study in order to characterize the composition of multi-component material (Adamson et al., 2007; Radziemski et al., 1983). It is especially suitable for field work by offering the possibility of real-time analysis with high portability. Thanks the above mentioned advantages, the LIBS technique has experienced strong growth, which is reflected in a large and growing number of publications. LIBS is not a new technique: firsts laser-induced breakdown studies go back to the early 1960s and important application studies date from the 1980s with the work of Radziemski (Tognoni et al., 2002). A comprehensive review of LIBS development and applications through the mid-1990s was produced by Rusak et al.(Rusak et al., 1997). The technique has many attributes that make it an attractive tool for chemical analysis, particularly as regards its potential as a field-portable sensor for geochemical analysis. LIBS is relatively simple and straightforward, so skilled analysts are not required. Little to no sample preparation is required, which eliminates the possibility of adulteration of the sample through improper handling or storage or cross-contamination during sample preparation. LIBS provides a real-time response and simultaneous multi-element detection and analysis. The laser plasma is formed over a very limited spatial area, so that only a very small amount of sample (picograms to nanograms) is engaged in each laser micro-plasma event. All components of the instrument can be made small and rugged for field use and LIBS sensors can be operated either as a point sensor or in a standoff detection mode. The

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detection limits of LIBS are in the low hundreds to tens of ppm range for most common elements, so field-portable LIBS should be capable of field surveying and screening for the geochemical exploration and environmental remediation applications envisaged. The existing equipment on the market used predominantly solid-state lasers based on Nd:YAG crystals. This is because this type of lasers, in addition to the advantages of robustness and compactness; allow obtaining very short pulses with high power density. To ensure the appropriate parameters, it works in the so-called Q: Switch regime. In this mode of operation, is introduced into the laser cavity an optical shutter based on a crystal whose transmittance is electrically switched, allowing the production of single-pulse of several nanoseconds in duration and very high intensity. In the last years several works have reported an improvement of plasma intensity, and therefore the limits and quality of detection, using systems that generate two consecutive pulses, delivered from one or two synchronized lasers (Tognoni et al., 2002). Recently, it was reported a system with dual crystal modulator by using two LiF crystals (Galbacs et al., 2005). While this system improved the signal-noise relation and the intensity of the plasma emission, has the disadvantage associated with the gradual degradation of these crystals (Zabello et al., 2003). In our study we propose a new low cost LIBS system, which uses passively Q:Switched, capable to produce pulse trains that enhances the plasma intensity. The employment of this regime is illustrated by LIBS characterization of art object. On the other hand, as an example of on-line monitoring of industrial process, and also the possibilities for different pulse regimes, we present the applications of free-running regime in the de-thorning process of cactus, a food Mexican product.

2. A low cost and portable LIBS device description Figure 1 shows an outline of the experimental setup. A Nd:YAG laser emitting at 1064 nm, produces pulses with energy adjustable up to 0.9 J. The active element is a 6 x 60 mm Nd:YAG rod, pumped by a xenon lamp. It uses a Q:Switch consisting of a Cr:YAG crystal with 6 mm in diameter and 3 mm in thick and initial transmittance of 14%. The light emitted by laser is focused through a 5 mm focal length lens. The distance between the lens and the surface of the sample was 8.5 cm to achieve an area of 0.19 cm2. For the experimental conditions used, this means a yield of 4.7 J/cm2. The sample is placed on metallic base ensuring that the sample surface is located at the focal point. An optical system coupled with the entry of optical quartz fiber, whose entry can be moved respect to the sample surface. By this way it is possible to capture the emission from a specific region of the plasma. The spectrometer used in our configuration was an USB4000 Ocean Optics, with 350 nm to 900 nm spectral range and 0.2 nm resolution. The spectra were processed in computer by using Spectra Suite software. 2.1 Nd:YAG laser with passive Q:Switch In the laser head of our device the pump radiation is produced by xenon pulse lamp. The light from this lamp is concentrated on the active medium of Nd:YAG through an special reflector made from monolithic quartz with external metallic coating. The quartz block is doped with atomic Ce at 1 % doping level. This feature avoids the optical damage of the active medium due the ultraviolet light emitted by xenon lamp. On the other hand, the

Burst Mode Q:switched Laser Pulses for Plasma Excitation in LIBS Analysis

85

conversion of UV to visible radiation contributes to enhance the absorption of pump light in laser crystal and, in consequence, the laser efficiency. For obtaining a compact device, the resonator mirrors of 99,8% and 50 % reflectance respectively, were placed at 1.5 cm form the rod ends. The rod dimensions are 5 x 50 mm. As a Q:Switch element a YAG:Cr crystal with dimensions 6 mm in diameter and 3 mm thick was used. The initial transmittance of Q:Switch was 21 % for 1064 nm wavelength. Mirror Laser

Pulse Generator O. fiber Lens

Spectrometer

Lens Array Sample

A/D Converter

Fig. 1. Schematic of experimental setup For this configuration, the laser can produce a train of pulses with duration for each pulse of about 20 ns, separated by 10 μs interval, with a total duration of the pulse train about 700 μs. In Figure 2 the acquired signal of laser pulse for passive Q:Switched laser is showed.

Fig. 2. Oscilogramme of pulse train obtained with passive Q:Switch. All system elements are mounted on a stereo-microscope in order to obtain better facility for positioning and observation of samples as well as to follow the results of irradiation. The dimensions and weight of LIBS device is 40 x 20 x 15 cm and 5 kg respectively. Figure 3 shows a photograph of device, called MicroLIBS.

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Fig. 3. Photograph of MicroLIBS system.

3. Results and discussion The use of LIBS as an analytical tool depends on three underlying assumptions: (i) that material ablation is stoichiometric so that the composition of the plasma generated is fully representative of the sample composition; (ii) that an optically thin plasma is generated so that emission from the central high-temperature portion of the plasma plume is not reabsorbed in the colder plasma boundary region; and (iii) the plasma is in local thermodynamic equilibrium. These conditions have been verified by Chan & Russo (Chan & Russo, 1991) and Corsi et al. (Corsi et al., 2000) and it is understood how to realize these conditions analytically. The use of LIBS for elemental detection is simple and readily accomplished via peak matching against a spectral library constructed in advance for a specific application. For this type of application, which can be accomplished through statistical analysis of LIBS spectra (Anzano et al., 2000), it is only relative peak intensities and overall spectral shape that is important, not absolute peak intensities. Quantitative LIBS analysis of specific elements in natural materials is significantly more difficult because of the broad issue known as “matrix effects”. This is an observed dependence of the intensity of the LIBS emission response to the nature of the material analysed (Eppler et al., 1996), which manifests as variations in laser-target coupling and resultant plasma intensity variations. These two facets of the sample, which are generally lumped together as “matrix effects”(Aguilera et al., 2009; Corsi et al., 2000; Ctvrtnickova et al.; Lu et al., 2010; Ma et al.; Mohamed, 2008; Shen et al., 2009; Windom & Hahn, 2009), will determine LIBS signal reproducibility, namely sample composition and sample surface character. 3.1 Multi-pulse excitation An important approach for enhance the detection limits and the signal-noise relation was reported early (Ponce et al., 2008), and consist in the use of passively Q:Switched multipulse scheme in order to perform the plasma formation-excitation process. In order to


87

establish a comparison, it was used an electro-optically Q:Switched Nd:YAG laser with similar parameters with the passively Q:Switched laboratory-made device. In the first case, the laser pulse energy of 0.14 J was focused on an area of 1 mm diameter, thus obtaining a fluency of 4.6 J/cm2, similar to that used in the passively Q:Switched laser. The only experimental difference: Pulse duration of 20 ns in single pulse configuration and 700 μs total duration for the multi-pulse configuration. In Figure 4 are observed an example of spectra captured for both lasers. The spectra chosen to illustrate the comparison were collected form Prickly Pears spines. As can be seen, are clearly identified several peaks associated with the CaII, MgII and CI. These peaks, like the rest of the spectrum, have higher intensity and better signal-noise relation for a train of pulses configuration. These results can be explained through a several steps process (Zabello et al., 2003). Initially, the absorption occurs in the first laser pulse at the sample surface, with the consequent overheating above the melting point. This causes the explosive material ablation, his rupture and rapid heating of the surrounding atmosphere, and a strong electronic emission. The steam flow expands and produces a shock wave, which in its motion dragging behind an area of low pressure. The initial pressure is restored after about 100 μs, as estimated experimentally (Kabashin et al., 1990).

Fig. 4. LIBS spectra captured by using multipulse (above) and single-pulse (below) configurations. By influencing subsequent pulses, separated from each other by a few tens of microseconds, the conditions for these interactions are the same as the first except for the presence of the above mentioned area of low pressure and a broadcast electronics (noise), much lower, because at that time the flow of electrons has disappeared. Moreover, the highest line intensity for multipulse regime can be explained by the additional excitation pulses produced in the steam of initially ejected material. Thus, the use of pulse trains by using passive Q:Switch, produce higher emission intensities and betters signal noise rate. 3.2 Free-running excitation Typically, the LIBS technique is performed using Q:Switched lasers with high power pulses (megawatt range), produced with time durations in nanosecond range. As far as we know,

88


no LIBS experiments were performed by using free-running regime until the recent reports of LIBS in Prickly Pear (Flores et al., 2009), because the low energy density for this mode of laser operation. However, in the mentioned report, due to the strong absorption in areoles, an intense plasma emission takes place even for microsecond range in pulse duration with kilowatts/cm2 range of laser fluency. As we demonstrated, this allows to use in experiments not only a Q:Switched laser but also a free running low cost Nd:YAG laser regime. The experiments in free-running regime have a great practical interest because at this regime is possible to obtain a higher productivity in spines elimination. On the other hand, the laser operating at this regime is less expensive and the operation cost is lower. At present, our research group is working of high energy and long pulse LIBS excitation, performed at millisecond pulse time duration. The special interest of this exotic conditions in plasma generation, is explained by two reasons: The possibility of simulation of some natural events like interstellar jets or atmospheric thunders from one side, and, the on-line monitoring of several industrial applications in millisecond range as hole perforation or pulse welding from the other side. In principle, as lower pulse duration them better resolution can be obtained, if we taking in to account the fact that typically with shorter pulse duration avoid higher power densities and better plasma ionization level. I also important the fact that the plasma life is extended no more than several microseconds, and, in consequence, if the pulse duration is longer, them the interaction with subsequent excitation must be taken in consideration in the LIBS spectra interpretation. As an example of line-width behaviour for different pulse duration, LIBS spectra captured on metal sample are showed in figure 5.

Fig. 5. LIBS spectra obtained from Cu sample.


89

3.3 Field applications: Free-running excitation for Cactus de-thorning An exciting example of our LIBS device is the on-line elemental determination for laser dethorning process. In this new application a Nd:YAG (Flores et al., 2009) laser is used for selective ablation of thorns of cactus called opuntia. In figure 6, is showed a deep-profile LIBS measurement of thorn-cortex systems illustrating the behavior of Na(I) 589.5 nm line and C-H band. These curves shows that LIBS technique contribute to control the spine elimination process: For C-H line the relative intensity reach the maximal value after two or three pulses and decrease gradually until the full thorn elimination reaching in this moment a fixed value that correspond to lower percent of C-H concentration in cortex. In opposite direction, the Na line intensity grows gradually reaching a higher level simultaneously with C-H decrease. The high concentration of Na in cortex is reached after spine elimination precisely when the inner part of cactus is to be ablated. On the other hand, it is another important difference between the two curves showed in figure 6. While the Na pike dependence versus number of pulses growth continuously, the C-H dependence shows periodical changes. It’s remarkable that similar variations were detected in previous work (Arronte et al., 2010), by photo-acoustic technique when the signal intensity versus number of pulses was measured. In principle, these changes can be attributed to periodical character of combustion process in laser de-thorning, consisting in

Fig. 6. Intensity profile curves Na I (589.5 nm) y emission band of the C-H clusters

90


several stages combustion-ablation: While the first pulse prepare the surface making it darker by combustion, the second pulse irradiate a surface with strong absorption and ablate it at very high rate. 3.4 Field applications: Bust mode Q:Switched excitation for LIBS analysis of art metal object LIBS offers a potential alternative to other techniques used in art conservation, works of art, archaeology, etc., being a rapid elemental analysis technique, performed in situ and virtually non-destructive (Fotakis 2006). A LIBS’s particularly interesting application is the analysis of metal objects with different compositional layers, particularly when trying to get in-depth composition profiles to distinguish the different elements present in a metal object and can develop a proper restoration process, among other uses, see Fig. 7a. Thus, the determination of the elemental composition, so far unknown, of the different layers present in a 20th Century Metal Jug, of Japanese origin, belonging to a private collection and the only one of its kind (see Figure 7b), is performed using a prototype LIBS equipment. For this purpose, successive burst mode laser pulses are applied to a well-localized area of the sample. The determination of the components avoid to the better selection of the restoration method to be used.

(a)

(b)

Fig. 7. (a) An schematic of in-depth laser microanalysis performed by LIBS technique, (b) The picture of Japanese Jug. A wide spectral window was selected, covering approximately 450 nm and that was centered at 575 nm, so that any elements contained in the metal object, including those elements that can arise by the influence of environmental factors such as Ca, Mg, Si, Al , Na and K, may be measured simultaneously. The Jug was analyzed superficially in four different and distant points to determine the surface composition and ensure the minimum possible sampling and thereby minimize damage as a result of ablation. The normalized characteristic spectrum for each of the samples is shown in the Figure 8. As shown, certain elements are represented in each of the measurements performed. The Cu constitutes the fundamental component and in turn the one that shows major proportion in relation to the other materials. Other elements were found to a lesser extent such as Ca, Si, Na and K, including marked relative differences between their intensities, showing changes in their proportions. These elements are attributed to deposition of dirt and impurities on the surface of the sample. Another element

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determined is the Pb which, similarly to the other aforementioned elements, has lower intensity values as compared to Cu. Finally, O and N were determined essentially using the same behavior in all measurements, and their presence is due to mainly the combustion process during the laser-matter interaction with the atmosphere, among others. Each time a laser pulse is applied on the surface of the Jug, a portion of the material that makes up the surface is removed and plasma is generated. If the laser is applied all the time in one place, it will penetrate the material (see Fig. 7a). In order to obtain the composition profile and identify different elements and layers present in the Jug, a multispectral analysis of the emission of the plasma generated by each laser shot was performed. The procedure to determine each layer consisted of recording pulse-to-pulse variations in the intensity of emission lines characteristics of maximum amplitude of the obtained constituent elements of the surface: Ca (II) 392.83 nm, Pb (I) 405.56 nm, Cu (I) 521.24 nm, Si (II) 546.04 nm, Na (I) 588.67 nm and K (I) 765.93 nm. The intensity of these elements depending on the number of pulses is shown in the Fig. 9. Cu Pb

P4 Pb Na

O Ca Ca Ca

N

Si Cu

Ca, Pb, Cu, Si, K

K

P3

P2

P1

400

450

500

550

600

650

700

750

Wavelength (nm)

Fig. 8. LIBS spectra obtained in four different zones of metal Jug. By increasing the number of pulses (greater penetration in the sample), the elements Ca, Si, Na, and K had a decreasing behavior. The little variation of intensity from pulse 4 indicates that the elements have virtually disappeared. The lack of a zero value is justified by the presence of background signal, which will have a greater or lesser value depending on the spectral region in which they are found. Low levels in the intensities of these elements, compared to Cu, involve small concentration values in the object. This supports the idea of the presence of elements resulting from the deposition of dirt and impurities on the Jug’s surface. Metal objects often show heterogeneity and surface oxidation caused by heat treatment during construction and environmental degradation. These factors can cause variation in the morphology and elemental composition of ancient metal alloys, which results in pollution of surface and global object.

92

Laser Pulse Phenomena and Applications 2000 1500

Pb

Relative Intensity (A.U.)

1000

Cu

500 0 1

2

3

4

5

6

7

8

9

10

11

12

13

800

K Na

600

Si Ca

400

200

0 1

2

3

4

5

6

7

8

9

10

11

12

13

Number of pulses Fig. 9. In-depth profiles for Ca(II) 392.83 nm, Pb(I) 405.56 nm, Cu(I) 521.24 nm, Si(II) 546.04 nm, Na(I) 588.67 nm and K(I) 765.93 nm as function of number of pulses. The Cu, during the first pulses (pulse 1 - pulse 3), shows increasingly higher intensity values, constituting the main element on the jug’s surface (pulse 1) and, turn on, a small interior portion of the jug. The Pb, initially (pulse 1) at very small intensity levels, has a linear increase until coming to its maximum value after pulse 4. After this pulse, the intensity of Cu starts to decrease until reaching a practically zero value. On the other hand, the Pb maintains a stable behavior during the following pulses. After pulse 13, virtually all elements have disappeared being the Pb the majority element in the jug’s composition. Figure 10 shows the superposition of the Jug’s spectrum, after pulse 13, with a spectrum pattern of Pb showing a perfect match between these spectrums. It is, therefore, evident the presence of two phases or layers in the Jug: phase 1 with Cu as the majority element, and phase 2 for Pb. On the other hand, the Cu-Pb interface, through the behavior between the intensity ratios of Cu/Pb and Pb, precisely on the pulse 4 is observed clearly in the Figure 11. Precisely, the Pb reaches its maximum value and the ratio Cu/Pb becomes lesser than 1 which, from the following pulses, tends linearly to zero. While the existence of two layers in the depth profile of the Jug was determined, from Figure 11 can be seen that the Cu layer, in addition to Ca, Si, Na and K, there is the presence of Pb. This result comes from the thickness of Cu layer and the laser energy. While energy was selected in an optimal work area; nonetheless, given the thickness of Cu layer, this energy level remains relatively

93


1.0

Jup3 P13 Pb


0.8

0.6

0.4

0.2

0.0

400

450

500

550

600

650

700

750

Wavelength (nm)

Fig. 10. Comparison between the spectra of metal Jug and Pb standard.

Cu 1

2

3

Pb 4

5

6

7

8

9

10 11 12 13 2000


8

1600 6

Cu/Pb Pb

1200

Interface

4

800 2

0

400

1

2

3

4

5

6

7

8

9

10 11 12 13

0

Number of pulses

Fig. 11. In-depth behavior of Cu/Pb rate and Pb relative intensity. sufficient to interact with the next layer (Pb) and generate also laser ablation. Similarly, the presence of Cu in the Pb layer can be seen in the Figure 9. In this case, the ratio is given in the form of how laser energy is distributed. The distribution of energy of the pulse laser is not exactly homogeneous (at the edges it is lower than in the center); so the amount of material removed from the irradiated region will be lower in edges than in the center, so that debris of the previous layer may be always remained as it moves in depth.20 From the crater produced by 13 laser pulses in interaction with the jug, the crater’s wall can be seen, see Figure 12.

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Fig. 12. Contrast image of laser treated zone captured by optical microscopy (magnification 60x). Referencing the image scale, the approximate depth of the crater can be determined. Therefore, knowing the depth of the crater and the number of pulses, it is possible to determine how much material is extracted in every interaction of laser with the Jug and, in turn, determine the thickness of Cu layer. Making the necessary calculations, we find that the thickness of the crater’s wall is approximately 88 μm, which implies, for a total of 13 laser pulses, a penetration factor of 6.8 μm/pulse. Therefore, as estimated, the thickness of Cu layer is 27 μm knowing that it ends after pulse 4.

7. Conclusions Recent technological advances are leading to the development of fully field-portable LIBS systems as show MicroLIBS, the compact, portable and low cost LIBS device developed by IMRE-Havana University. The use of Cr:YAG crystal as Q:Switch element allows simplifying the design and reducing costs as compared to electro-optical Q:Switch and also to guarantee more duration that LiF elements. The application of pulse trains as an excitation source helps to achieve a higher intensity of plasma emission and a substantial improvement in the signal-to-noise ratio compared with single-pulse systems. The advances in modification of laser parameters open new applications no limited to elemental determination but also covering the laser material processing on-line monitoring or the simulation of specific plasma events in wide range of energies or pulse durations. Regarding the fields applications, two examples were given: On one side, the real-time monitoring of de-thorning process for one food product, and, on the other side, the compositional characterization of heritage object. For the first field application, the burst-mode excited LIBS technique is shown to be a suitable method for new industrial processes. Additionally, the approach of complex band emission pattern recognition can be used for determining of contamination problems in such vegetable food. For the case of metal Jug analysis, the multi-pulse regime shows the possibilities of the technique for heritage objects characterization. The presence of key elements (Cu and Pb) was determined. They are distributed in layers, being the Cu the surface element with an estimated thickness of 27 um. The elements Ca, Si, Na and K are impurities caused by dirt and the environment that influence the object's surface. In resume, the multi-pulse excited LIBS technique serves as an in situ, low-cost and virtually non-destructive analytical tool, in the identification of elements and environmental monitoring or characterizing a wide spectrum of process and objects.


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8. References Adamson, M., Padmanabhan, A., Godfrey, G.J., Rehse, S.J., 2007, Laser-induced breakdown spectroscopy at a water/gas interface: A study of bath gas-dependent molecular species. Spectrochimica Acta Part B: Atomic Spectroscopy 62, 1348-1360. Aguilera, J.A., Aragón, C., Madurga, V., Manrique, J., 2009, Study of matrix effects in laser induced breakdown spectroscopy on metallic samples using plasma characterization by emission spectroscopy. Spectrochimica Acta - Part B Atomic Spectroscopy 64, 993-998. Anzano, J.M., Gornushkin, I.B., Smith, B.W., Winefordner, J.D., 2000, Laser-induced plasma spectroscopy for plastic identification. Polymer Engineering and Science 40, 24232429. Arronte, M., Ortega, E., Ponce, L., de Posada, E., Rodriguez, E., Flores, T., 2010. Real-time monitoring of de-thorning process in Opunctia Nopalea by using a PILA technique. Acoustic Technique 1, 1-10. Corsi, M., Palleschi, V., Salvetti, A., Tognoni, E., 2000, Making LIBS quantitative: A critical review of the current approaches to the problem. Research Advances in Applied Spectroscopy 1, 41-46. Cremers, D.A., 2007, Remote Analysis by LIBS: Application to Space Exploration, In: Jagdish, P.S., Surya, N.T. (Eds.) Laser-Induced Breakdown Spectroscopy. Elsevier, Amsterdam, pp. 353-379. Cremers, L.J.R.a.D.A., 2006, Laser-Induced Breakdown Spectroscopy (LIBS): Fundamentals and Applications. Ctvrtnickova, T., Mateo, M.P., Yañez, A., Nicolas, G., Laser Induced Breakdown Spectroscopy application for ash characterisation for a coal fired power plant. Spectrochimica Acta - Part B Atomic Spectroscopy. Chan, W.T., Russo, R.E., 1991, Study of laser-material interactions using inductively coupled plasma-atomic emission spectrometry. Spectrochimica Acta Part B: Atomic Spectroscopy 46, 1471-1486. Eppler, A.S., Cremers, D.A., Hickmott, D.D., Ferris, M.J., Koskelo, A.C., 1996, Matrix effects in the detection of Pb and Ba in soils using laser-induced breakdown spectroscopy. Applied Spectroscopy 50, 1175-1181. Flores, T., Ponce, L., Arronte, M., de Posada, E., 2009, Free-running and Q:Switched LIBS measurements during the laser ablation of Prickle Pears spines. Optics and Lasers in Engineering 47, 578-583. Galbacs, G., Budavan, V., Geretovszky, Z., 2005, Multi-pulse laser-induced plasma spectroscopy using a single laser source and a compact spectrometer. Journal of Analytical Atomic Spectrometry 20, 974-980. Kabashin, A.V., Konov, V.I., Nikitin, P.I., Prokhorov, A.M., Konjević, N., Vikor, L., 1990, Laser-plasma generation of currents along a conductive target. Journal of Applied Physics 68, 3140-3146. Lu, Y.F., Shen, X.K., Ling, H., 2010. Laser-induced breakdown spectroscopy combined with spatial confinement of plasmas and laser-induced fluorescence for trace-materials detection. In, Shanghai, pp. 697-704. Ma, Q.L., Motto-Ros, V., Lei, W.Q., Boueri, M., Zheng, L.J., Zeng, H.P., Bar-Matthews, M., Ayalon, A., Panczer, G., Yu, J., Multi-elemental mapping of a speleothem using

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laser-induced breakdown spectroscopy. Spectrochimica Acta - Part B Atomic Spectroscopy. Mohamed, W.T.Y., 2008, Improved LIBS limit of detection of Be, Mg, Si, Mn, Fe and Cu in aluminum alloy samples using a portable Echelle spectrometer with ICCD camera. Optics and Laser Technology 40, 30-38. Ponce, L., Flores, T., Arronte, M., Hernandez, L.C., Bilmes, G.M., Alvira, F., 2008, Laser Induced Breakdown Spectroscopy widh multi-pulse excitation. Revista Cubana de Física, 25, N2A, pp. 85-87. Radziemski, L.J., Loree, T.R., Cremers, D.A., Hoffman, N.M., 1983, Time-resolved laserinduced breakdown spectrometry of aerosols. Analytical Chemistry 55, 1246-1252. Rusak, D.A., Castle, B.C., Smith, B.W., Winefordner, J.D., 1997, Excitational, vibrational, and rotational temperatures in Nd:YAG and XeCl Laser-Induced plasmas. Spectrochimica Acta Part B: Atomic Spectroscopy 52, 1929-1935. Rusak, D.A., Castle, B.C., Smith, B.W., Winefordner, J.D., 1998, Recent trends and the future of laser-induced plasma spectroscopy. TrAC - Trends in Analytical Chemistry 17, 453-461. Shen, X.K., Ling, H., Lu, Y.F., 2009. Laser-induced breakdown spectroscopy with high detection sensitivity. In, San Jose, CA. Song, K., Lee, Y.I., Sneddon, J., 1997, Applications of laser-induced breakdown spectrometry. Applied Spectroscopy Reviews 32, 183-235. Tognoni, E., Palleschi, V., Corsi, M., Cristoforetti, G., 2002, Quantitative micro-analysis by laser-induced breakdown spectroscopy: A review of the experimental approaches. Spectrochimica Acta - Part B Atomic Spectroscopy 57, 1115-1130. Windom, B.C., Hahn, D.W., 2009, Laser ablation - Laser induced breakdown spectroscopy (LA-LIBS): A means for overcoming matrix effects leading to improved analyte response. Journal of Analytical Atomic Spectrometry 24, 1665-1675. Zabello, E., Syaber, V., Khizhnyak, A., 2003. Spectral-analytical characteristics of laser plasma under multi-pulse excitation regime. In, pp. 220-222. Fotakis, C., Lasers in the Preservation of Cultural Heritage; Principles and applications, Institute of Physics Publishing , (New York, 2006).

6 Numerical Simulations of Temperaturedependence on Distributed Bragg Reflector (DBR) and Performance Analyses for ProtonImplant/Oxide Confined VCSEL: Comparison with Transmission Matrix, Matrix Calculating Methods and Macleod Model Tzu-Chiang Chen

Chung Cheng Institute of Technology, National Defense University Taiwan, Republic of China 1. Introduction This chapter mainly focuses on the simulation for temperature-dependent Distributed Bragg Reflector (DBR) of 850nm vertical cavity surface emitting laser (VCSEL) with Transmission Matrix (TMM), Matrix Calculating Methods (MCM) and Macleod Model and performance for comparison with proton-implant/oxide confined process on VCSEL. Using welldeveloped temperature-dependent DBR-reflectivity solver with Mathcad simulator, we have successfully compared the Macleod Model simulator with theoretical self-developed solution based on the Transmission Matrix (TMM), Matrix Calculating Methods (MCM) and find very good agreement with previous results while accounting for influences of conjugated part of refractive index and graded Al compositions of DBR materials. Moreover, optoelectronic performance of Proton-Implant/Oxide Confined 850 nm VCSEL have been demonstrated on this chapter using temperature-dependent power output, voltage/injection current, transverse operating wavelengths, optical spectral characteristics, slope efficiency and transverse optical modes with an approximated Marcatili's method extracted and measurement from systematically measuring experiments. Through adequate and precise LD device design and processes, we have proposed the high performance single-mode proton implanted in contrast to the oxide confined 850 nm VCSEL. Under nominal temperature-variety and keeping operating temperature of 30 °C, the maximum power output of 10 micro meter aperture proton implanted VCSEL exceeds 5 mW while injecting current of 10 mA, and the threshold voltage, injecting current, peak-wavelength, differential resistance are 1.8 V, 3.2 mA, 851 nm and 36.8 ohm, respectively.

2. Research focuses Vertical cavity surface emitting laser has a number of inherent advantages including low divergence of the circular beam, which is emitted from the top surface of the laser diode in

98


order to efficiently couple into fiber for communication. One of the most unique characteristic operation of a VCSEL is that it operates in single longitudinal mode due to its natively short effective cavity length. And many researchers also try to achieve high efficiency, high power, single transverse mode operation and insensitive temperature feature in VCSEL for high-speed light-wave communication and higher information capacity of the communication-linking network. By far, the common compound semiconductor material used for fabricating the reflector mirrors of VCSEL is the AlGaAs system because of the large refractive index difference between the lattice matched GaAs and AlAs binaries. J. Talghader et.al. have investigated the thermal dependence of the refractive index of GaAs and AlAs measured using semiconductor multiplayer optical cavities (J. Talghader et.al., 2003). The VCSEL-type passive optical cavities exhibiting substantially different longitudinal optical mode shifts with temperature has been demonstrated. For conventional edge-emitting semiconductor lasers, the far-field and beam characteristics depend on laser structure. However, the detailed study of far-field modes and beam features for VCSEL with different window diameters (ω) and active-layer apertures (s) as function of injected current has been proposed at a certain temperature (Iga, K. et.al., 1984). In our study, the temperature-dependent reflectivity spectra of linear graded Al-composition DBR in 850 nm-VCSEL were simulated and analyzed using two-kinds of transfer matrix methods, which compared with the results from the multi-layer films evolution software of essential Macleod. To our knowledge, little work has yet investigated the thermal effect on spatial distributions of far-fields patterns. So, the influences of injected current and temperature-varying have been displayed in this work.

3. Theory and experimental setups 3.1 Description of VCSEL structure The VCSEL studied are 1λ cavity length, GaAs quantum well (QW)-based structure with 15 μm-circular selectively oxided cavity apertures for current confinement. As seen in Fig.1, the DBR mirrors were formed with alternating layers of top graded mirrors of 20 pairs of AlxGa1-xAs/AlyGa1-yAs (x= 0~0.9, y= 0~0.12) quarter-wave stacks and a bottom mirror of 34 pairs of AlyGa1-yAs/AlxGa1-xAs quarter-wave stacks. The graded Al composition in DBR mirrors is to built electric field uniformly in the VCSEL structure which avoid sharp energy discontinuity between DBR and active region. Three periods of quantum wells are sandwiched with double DBRs and centered in active region; lasing occurs in the 850 nm p-DBR

20 pairs 3x Quantum wells Oxide layer

n-DBR

34 pairs

GaAs substrate Fig. 1. Structure of the selectively oxidized VCSEL with circular aperture of 10μm in diameter and with active region of quantum well as the gain medium

Numerical Simulations of Temperature-dependence on Distributed Bragg Reflector (DBR) and Performance Analyses for Proton-Implant/Oxide Confined VCSEL: Comparison with …

99

range for the fundamental mode. The excess two thin layers of Al0.98Ga0.02As are oxidized to efficiently form a circular aperture. The top and bottom DBR mirrors were doped moderately for decreasing the series resistance of VCSEL. 3.2 Calculation of refractive index of AlxGa1-xAs We use a semi-empirical method for calculating the room temperature refractive index of AlxGa1-xAs at energies below the direct band edge and this quantity is important in the design of GaAs heterostructure lasers. M. A. Afromowitz has used the interpolation scheme and compare the results of the calculation of refractive index for the AlxGa1-xAs with experimental data (M. A. Afromowitz, 1974). From this model, these equation of n(x,λ) reproduces as yielding, ⎡E x E x ×E 2 λ ⎛ 2 × Eo2 ( x) − EΓ2 ( x) − Ep2 ( λ ) ⎞⎤ Ed ( x) × Ep4 ( λ ) ( ) + d( ) p ( ) + ⎟⎥ + 1 (1) × ln ⎜ n(x, λ ) = ⎢ d 3 ⎢ E ( x) ⎜ ⎟⎥ Eo ( x) EΓ2 ( x) − Ep2 ( λ ) 2 × Eo3 ( x) × Eo2 ( x) − EΓ2 ( x) ⎝ ⎠⎥⎦ ⎢⎣ o

(

)

where n denotes the refractive of AlxGa1-xAs, x : Al composition, λ: optical light wavelength, Ep: incident optical energy, E0: effective oscillated energy, Ed: dispersion energy, and EГ: band gap energy. The equations for E0, Ed , and EГ as the function of alloy composition yield Ep ( λ ) =

1.239852066 × 10 3

(2)

λ

Eo ( x ) = 3.65 + 0.871 × x + 0.179 × x 2

(3)

Ed ( x ) = 36.1 − 2.45 × x

(4)

EΓ ( x ) = 1.424 + 1.266 × x + 0.26 × x 2

(5)

In this section, using two kinds of described methods for transfer matrix method simulate DBR mirrors (C. Chen, 2002). The detailed deduction of the models as follows: 3.3 Transmission matrix method, TMM (Furman, Sh.et.al., 2002) Consider the optical waves are propagated along with z-direction as shown in Fig. 2 And the electric fields display as the next two equations: A j ( z2 ) = e

− j β i ( z2 − z1 )

B j ( z2 ) = e

j β i ( z2 − z1 )

Ai ( z2 )

(6)

Bi ( z2 )

β i = koni = ko ( ni ,re + ni ,im ) ko =

(7) 2π

λ

(8)

where β i is propagation constant, ko : wave number, ni : complex refraction index, ni ,re : refraction index, ni ,im : extinction coefficient

100


For the purpose of convenience, the equations (6) and (7) can be achieved as matrix type： ⎡ A j ( z2 ) ⎤ ⎡ e − j β i L ⎢ ⎥=⎢ ⎣⎢ B j ( z2 ) ⎦⎥ ⎣⎢ 0

⎡ Ai ( z1 ) ⎤ 0 ⎤ ⎡ Ai ( z1 ) ⎤ ⎥⎢ ⎥ = Pi ⎢ ⎥ e ⎦⎥ ⎢⎣ Ai ( z1 ) ⎥⎦ ⎢⎣ Ai ( z2 ) ⎥⎦

(9)

jβi L

where Pi is propagation matrix, L = Z2 − Z1 , Z1

Z2

Ai

Aj I Bj

Bi

L

Fig. 2. Schematic diagram of wave propagation in region I The optical waves are transmitted through the different interface regions as plotted in Fig.3, using the below boundary conditions:

A j + Bj = Ai + Bi

(10)

−n j A j + n j Bj = −ni Ai + ni + Bi

(11)

then let equation (10) and (11) exhibit as 2-dimensional matrix type, ⎡ n j + ni ⎢ A ⎡ j ⎤ ⎢ 2n j ⎢ ⎥=⎢ ⎣⎢ Bj ⎦⎥ ⎢ n j − ni ⎢ 2n j ⎣

n j − ni ⎤ ⎥ 2 n j ⎥ ⎡ Ai ⎤ ⎡ Ai ⎤ ⎢ ⎥ = Tj , i ⎢ ⎥ n j + ni ⎥ ⎣ Bi ⎦ ⎣ Bi ⎦ ⎥ 2 n j ⎥⎦

in where Tj ,i is propagation between matrix medium i and medium j.

ni

nj

Ai

Aj

Bi

Bj

Fig. 3. Schematic diagram of wave propagation in interface between ni and nj

(12)


101

Now, the structure with multi-layer stacks is displayed in Fig. 4, then the scheme of wave propagation can be written with propagation matrix form,

⎡ A2 ⎤ ⎡ A1 ⎤ ⎢ ⎥ = TP ⎢ ⎥ B 2 ⎣ ⎦ ⎣ B1 ⎦

(13)

t ⎤ ⎡t TP = T1,2 P2T2 ,1 P1 = ⎢ 11 12 ⎥ ⎣t21 t22 ⎦

(14)

Assume A2= 0, the reflective coefficient can be written as:

R1 =

A1 t = − 12 B1 t11

(15)

then the reflective ratio is shown as

R = R1 A1 B1

2

(16)

A2 B2 n1

n2

n1

n2

L1

L2

…………

L1

L2

Fig. 4. The multiplayer structure consists of n1and n2 mediums 3.4 Matrix calculating method, MCM (Furman, Sh.et.al., 2002) Consider the multiplayer structure as plotted in Fig. 5, the electric field u(z) in layer j and magnetic field v(z) are located in contiguous interface. While applying the boundary conditions of transverse electric field, the overall transfer matrix from the first to the M layer can be exhibited in the below matrix:

⎛ ⎜ cos ϕ j ⎛u⎞ = ⎜ ⎟ ⎜ v ⎝ ⎠ z = z j ⎜ iq sin ϕ j ⎝ j where ϕ j = kn j d j , k =

2π

λ

⎞ ⎛ i ⎞ ⎜ q ⎟ sin ϕ j ⎟ ⎛ u ⎞ j ⎝ ⎠ ⎟⎜ ⎟ ⎟ ⎝ v ⎠z= z j −1 cos ϕ j ⎠

, d j = z j − z j − 1 , q j = n j , let ⎛ ⎜ cos ϕ j Mj = ⎜ ⎜ iq sin ϕ j ⎝ j

⎞ ⎛ i ⎞ ⎜ q ⎟ sin ϕ j ⎟ j⎠ ⎝ ⎟ ⎟ cos ϕ j ⎠

(17)

102


For a series of multi-layer structure, the overall transfer is the product of individual transfer, i.e., ⎛u⎞ ⎛u⎞ = Mm Mm −1 … M1 ⎜ ⎟ ⎜ ⎟ v ⎝ ⎠ z = za ⎝ v ⎠z=0

⎛m M = M m M m − 1 … M 1 = ⎜ 11 ⎝ m21

(18)

m12 ⎞ ⎟ m22 ⎠

(19)

According to overall transfer matrix, the reflective coefficient can be written as: r=

nam11 − nsm22 + nans m12 − m21 nam11 + nsm22 + nansm12 + m21

(20)

so, the reflective ratio is described as R= r

Substrate

2

(21)

nm

n1

ns

nj

z0=0

na

dj

d1

z1

zj-1

Outer space

dm

zj

zm-1

zm=za

Fig. 5. The schematic diagram of multilayers consisting of substrate and outer space For further verifying the precision of reflectivity spectra using TMM and MCM method, the multi-layer films evolution software of essential Macleod is utilized to simulate for the same 850nm-VCSEL structure which includes the database built-up refractive index with respect to linearly graded Al composition from equation (1) to (5). The schematic diagrams of unit period in top and bottom DBR mirrors are shown as Fig. 6(a) and (b), respectively. The unit period of bottom DBR mirror consisting of 4 layers of AlxGa1-xAs(x: 0.12→0.9), Al0.9Ga0.1As, AlxGa1-xAs(x: 0.9→0.12) and Al0.12Ga0.88As is quasi-symmetric to top one for AlxGa1-xAs (x: 0.9→0.12), Al0.12Ga0.88As, AlxGa1-xAs (x: 0.12→0.9) and Al0.9Ga0.1As. However top and bottom DBR mirrors have 20 and 34 periods, respectively from theoretical calculations. From simulated results as shown in Fig. 7 and 8, it is notable that the reflectivity spectra achieved from TMM and MCM method are well agreed with the ones from using Macleod software at room temperature. The maximum reflectivity of top and bottom DBR mirrors are >96.4% and 99.98%. The peak wavelengths are located in 840 nm. It can overall satisfy the specification of high DBR performance.


Al0.9Ga0.1As

Al0.12Ga0.88As

AlxGa1-xAs (x:0.12→0.9)

AlxGa1-xAs (x:0.9→0.12)

Al0.12Ga0.88As

Al0.9Ga0.1As

AlxGa1-xAs (x:0.9→0.12)

AlxGa1-xAs (x:0.12→0.9)

GaAs substrate

GaAs substrate

103

Fig. 6. Unit periods of (a) top and (b) bottom DBR mirror

Reflectivity (%)

100

Macleod MCM TMM

80 60 40 20 0 750

800 850 900 Wavelength (nm)

950

Fig. 7. The spectra of top-DBR mirror

Reflectivity (%)

100

Macleod MCM TMM

80 60 40 20 0 750


950

Fig. 8. The spectra of bottom-DBR mirror Next, considering the temperature-dependent refractivity of DBR mirrors, it is due to the changes of refractive indexes in linearly graded AlxGa1-xAs and GaAs. (J. Talghader et.al., 2003) as follows:

( dn dT )

GaAs

= ( 2.67 ± 0.07 ) × 10 −4 / °C,

(22)

104


( dn dT )

AlAs

= ( 1.43 ± 0.07 ) × 10 −4 / °C

(23)

Estimate the temperature influences on reflectivity spectra from adding the equation (22) and (23) into the previous TMM, MCM method and material database in Macleod software. From Fig. 9 and 10, it is only 0.5Å/°C of spectra red-shift in DBR mirrors from 30 to 80°C, which are comparable with the proposed results from J. L. Shen et.al. (S. Chuang, 1995)

Reflectivity (%)

100

o

30oc 50oc 80 c

80 60 40 20 0 750


950

Fig. 9. The temperature dependent spectra of top-DBR mirror 30oC 50oC 80oC

Reflectivity (%)

100 80 60 40 20 0 750


950

Fig. 10. The temperature dependent spectra of top-DBR mirror

4. Theory of optical dielectric slab waveguides (S. Chuang, 1995) The dielectric waveguide theory is very useful studying heterojunction semiconductor lasers and the far-field patterns of VCSEL can be explained with the optical waveguide theory in our experiments. At first, let us consider a slab waveguide as shown in Fig. 11, where the width w >>thickness d, and the field dependence on y is negligible, i.e., ∂ / ∂y ≡ 0 . From the wave equation

(∇

2

)

+ ω 2 με E = 0

(24)

We shall find the solutions for the fields everywhere. We assume that the waveguide is symmetric, that is, the permittivity and the permeability are ε and μ, respectively, for


105

|x|0d/2, and ε1 and μ1 for |x|

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